Drill string inground isolator in an mwd system and associated method

ABSTRACT

An inground isolator and associated method can provide an electrically isolated break in a drill string using electrical insulating members/isolators that are supported by a housing. During drill string operations, the isolators are subject only compressive forces responsive to both extension (pushing) and retraction (pulling) by the drill string. The isolators can be formed from an electrically insulating material such as a ceramic material. An interchangeable inground tool system is described which integrally serves to provide an electrically isolating gap in the drill string.

BACKGROUND

The present application is generally related to inground operations and,more particularly, to a system, apparatus and method for electricallycoupling an electrical signal onto an electrically conductive drillstring for purposes of transferring the signal.

Generally, an inground operation such as, for example, drilling to forma borehole, subsequent reaming of a borehole for purposes of installinga utility line, borehole mapping and the like use an electricallyconductive drill string which extends from an above ground drill rig.The prior art includes examples of the use of an electrically conductivedrill string as an electrical conductor for serving to electricallyconduct a data signal from an inground tool to the drill rig. Thesurrounding earth itself serves as a signal return path for purposes ofdetecting the signal at the drill rig. This type of system is oftenreferred to as a Measurement While Drilling, MWD, system.

An example of an attempt to use the drill string as an electricalconductor in an MWD system is seen, for example, in U.S. Pat. No.4,864,293 (hereinafter, the '293 patent). In one embodiment, the patentteaches an electrically isolated collar that is fitted around the drillstring. Applicants recognize that the use of such an electricallyisolated collar (FIG. 2, item 32) is problematic at least with respectto durability in what can be an extremely hostile inground environment.In another embodiment, shown in FIGS. 3 and 4, a suitable dielectricseparator 40 is diagrammatically shown and asserted to electricallyisolate a front section of the drill string from the remainder of thedrill string. No detail is provided that would reasonably teach one howto fabricate this separator, but it is reasonable to assume that theisolator would simply be inserted into a break in the drill string forco-rotation therewith. Unfortunately, the isolator would then be subjectto the same rigorous mechanical stresses during the drilling operationas the drill pipe sections of the drill string including pure tensionforce during pullback operations and high shear forces due to rotationaltorque that is applied to the drill string by the drill rig. While thedrill string is generally formed from high strength steel that canreadily endure these forces, Applicants are unaware of any currentlyavailable non electrically conductive material that is capable ofenduring all these different forces with a reliability that Applicantsconsider as acceptable. It should be appreciated that the consequencesof breaking off the end of the drill string during a drilling operationare extremely severe. Thus, the risk introduced through the use of anisolator in the suggested manner is submitted to be unacceptable.

An even earlier approach is seen in U.S. Pat. No. 4,348,672 in which anattempt is made to introduce an electrically isolating break in thedrill string using various layers of dielectric material that areinterposed between the components of what the patent refers to as an“insulated gap sub assembly” that is made up of first and second annularsub members. One embodiment is illustrated by FIGS. 5 and 6 whileanother embodiment is illustrated by FIGS. 7 and 8 of the patent.Unfortunately, the practice of interposing relatively thin dielectriclayers in a gap defined between adjacent high-strength metal components,that are competent to withstand extreme forces as well as a hostiledownhole environment, is unlikely to provide an acceptable level ofperformance. In particular, these dielectric layers are subjected to thesame severe forces as the first and second annular sub members such thatdurability in a hostile downhole environment is most likely to belimited. That is, the desired electrical isolation will be compromisedat the moment that one of the relatively thin dielectric layers is wornthrough.

Practical approaches with respect to coupling an electrical signal ontoa drill string in the context of an MWD system are seen, for example, inU.S. patent application Ser. No. 13/035,774 (hereinafter the '774application) and U.S. patent application Ser. No. 13/035,833(hereinafter, the '833 application), each of which is commonly ownedwith the present application and each of which is incorporated herein byreference in its entirety. The latter applications take the highlyeffective approach of using a downhole current transformer toinductively couple a downhole signal onto the drill string while stillmaintaining physical performance characteristics that are comparable tothose of the drill string itself. While the '774 and '833 applicationsprovided sweeping advantages over the then-existing state of the art,Applicants have discovered other highly advantageous approaches, as willbe described hereinafter.

The foregoing examples of the related art and limitations relatedtherewith are intended to be illustrative and not exclusive. Otherlimitations of the related art will become apparent to those of skill inthe art upon a reading of the specification and a study of the drawings.

SUMMARY

The following embodiments and aspects thereof are described andillustrated in conjunction with systems, tools and methods which aremeant to be exemplary and illustrative, not limiting in scope. Invarious embodiments, one or more of the above-described problems havebeen reduced or eliminated, while other embodiments are directed toother improvements.

In one aspect of the disclosure, an apparatus and associated method aredisclosed for use in combination with a drill string that iselectrically conductive and extends from an inground distal end, thatincludes an inground tool, to a drill rig. In an embodiment, theapparatus includes a first group of electrical isolators and a secondgroup of electrical isolators. A housing defines a through passage andincludes a length that is configured to support the first group and thesecond group in a spaced apart relationship along said length andsurrounding the through passage such that, responsive to the drill rigpushing on the drill string, a first one of the first and second groupsis subject to a first compressive force and responsive to the drill rigpulling on the drill string the other one of the first and second groupsis subject to a second compressive force without subjecting either ofthe first and second groups to a tension force during said pushing andpulling by the drill rig to form an electrically isolating break in thedrill string. In one feature, responsive to the drill rig pushing on thedrill string, a first one of the first and second groups is subject tothe first compressive force without subjecting the second group to thefirst compressive force and, responsive to the drill rig pulling on thedrill string, a second one of the first and second groups is subject tothe second compressive force without subjecting the other one of thefirst and second groups to the second compressive force.

In another aspect of the disclosure, an apparatus and associated methodare described for use in combination with a drill string that iselectrically conductive and extends from an inground distal end, thatincludes an inground tool, to a drill rig. The drill rig is configuredto rotate the drill string which applies a rotational torque to thedrill string. A housing is configured to support a group of electricalisolators to electrically isolate a downhole portion of the drill stringfrom an uphole portion of the drill string such that the group ofelectrical isolators is subject only to a compressive force responsiveto the rotational torque.

In still another aspect of the present disclosure, an apparatus andassociated method are described for use in combination with anelectrically conductive drill string and which drill string extends froman inground distal end, including an inground tool, to a drill rig. Aplurality of electrical isolators is provided. A housing an elongatedhousing length that is configured to support the plurality of electricalisolators under a compressive preload that is applied by the housing ina direction that is aligned with the elongated housing length such thatan overall compressive force that is applied to the electrical isolatorsvaries responsive to push and pull forces that are applied to the drillstring by the drill rig and the electrical isolators cooperate with thehousing to form an electrically isolating gap between the ingrounddistal end and the drill rig.

In a continuing aspect of the present disclosure, an apparatus andassociated method are described for use in combination with a drillstring that is electrically conductive and extends from an ingrounddistal end that includes an inground tool, to a drill rig. A first groupof electrical isolators and a second group of electrical isolators areprovided. A first housing body is electrically conductive and defines afirst drill string fitting. A second housing body is also electricallyconductive and includes opposing first and second ends. The secondhousing body is configured to cooperate with the first housing body tosupport the first group of electrical isolators at the first end of thesecond housing body and the second group of electrical isolators at thesecond end of the second housing body such that the first housing bodyis electrically isolated from the second housing body. Aninterchangeable body, that is electrically conductive, is configured forremovably fixed engagement with the second end of the second housingbody. The interchangeable body is selectable as each of (i) the ingroundtool to form the inground distal end of the drill string and (ii) asecond, opposing drill string fitting such that the apparatus isinsertable into a joint in the drill string that would otherwise beformed between adjacent drill rods as the drill string is extended.

BRIEF DESCRIPTIONS OF THE DRAWINGS

Exemplary embodiments are illustrated in referenced figures of thedrawings. It is intended that the embodiments and figures disclosedherein are to be illustrative rather than limiting.

FIG. 1 is a diagrammatic view, in elevation, of a system which utilizesan embodiment of an inground isolator and inground signal couplingmethod of the present disclosure.

FIG. 2 is a diagrammatic view, in perspective, which illustrates anembodiment of the isolator of the present disclosure in an assembledform.

FIG. 3 is a diagrammatic, exploded perspective view of the embodiment ofthe isolator of FIG. 2.

FIG. 4 is another diagrammatic, exploded perspective view of theembodiment of the isolator of FIG. 2.

FIG. 5 is a diagrammatic partial view, in perspective, of selectedcomponents of the embodiment of the isolator of FIG. 2, shown here toillustrate these selected components in an assembled relationship.

FIG. 6 is a diagrammatic cutaway view, in elevation, of the embodimentof the isolator of FIG. 2, shown here to illustrate further details ofits structure.

FIG. 7 is a diagrammatic view, in perspective, of a boring tool coupledto inground isolator of the present disclosure and with the ingroundisolator also connected to an uphole portion of a drill string.

FIG. 8 is a diagrammatic view, in perspective, of an embodiment of areaming tool arrangement that is removably attached to the ingroundisolator of the present disclosure, shown connected to an uphole portionof the drill string.

FIG. 9 is a block diagram of an embodiment of a downhole electronicssection that is suitable for use with an embodiment of the ingroundisolator of the present disclosure.

FIG. 10 is a block diagram of an embodiment of an uphole electronicssection that is suitable for use at the drill rig for bidirectionalcommunication with a downhole electronics section via the isolator ofthe present disclosure and further including an inset view whichillustrates a repeater embodiment of the isolator of the presentdisclosure and associated electrical connections which transform theelectronics section for downhole repeater use.

FIG. 11 is a diagrammatic assembled view, in perspective, showinganother embodiment of an inground isolator according to the presentdisclosure.

FIG. 12 is a diagrammatic, exploded perspective view of the embodimentof the isolator of FIG. 11.

FIG. 13 is another diagrammatic, exploded perspective view of theembodiment of the isolator of FIG. 11.

FIG. 14 is a cut-away diagrammatic perspective view of an embodiment ofan inground tool according to the present disclosure which integrallyprovides an inground isolator configuration according to the presentdisclosure.

FIGS. 15 and 16 are diagrammatic exploded views, taken from differentperspectives, of the inground tool of FIG. 14, shown here to illustratedetails of its structure.

FIG. 17 is a diagrammatic view, in perspective, of an embodiment of aninground tool system and associated components in accordance with thepresent disclosure wherein the inground tool is interchangeable among avariety of different tools that are directed to different types ofinground operations.

FIG. 18 is an exploded diagrammatic view, in perspective, of theinground tool system of FIG. 17, shown here to illustrate details of itsinternal structure.

DETAILED DESCRIPTION

The following description is presented to enable one of ordinary skillin the art to make and use the invention and is provided in the contextof a patent application and its requirements. Various modifications tothe described embodiments will be readily apparent to those skilled inthe art and the generic principles taught herein may be applied to otherembodiments. Thus, the present invention is not intended to be limitedto the embodiments shown, but is to be accorded the widest scopeconsistent with the principles and features described herein includingmodifications and equivalents, as defined within the scope of theappended claims. It is noted that the drawings are not to scale and arediagrammatic in nature in a way that is thought to best illustratefeatures of interest. Descriptive terminology may be used with respectto these descriptions, however, this terminology has been adopted withthe intent of facilitating the reader's understanding and is notintended as being limiting.

Turning now to the figures wherein like components are indicated by likereference numbers throughout the various figures, attention isimmediately directed to FIG. 1 which is an elevational view thatdiagrammatically illustrates an embodiment of a horizontal directionaldrilling system generally indicated by the reference number 10 andproduced in accordance with the present disclosure. While theillustrated system shows the invention within the framework of ahorizontal directional drilling system and its components for performingan inground boring operation, the invention enjoys equal applicabilitywith respect to other operational procedures including, but not limitedto vertical drilling operations, pullback operations for installingutilities, mapping operations and the like.

FIG. 1 illustrates system 10 operating in a region 12. System 10includes a drill rig 14 having a drill string 16 extending therefrom toan inground tool 20. The drill string can be pushed into the ground tomove inground tool 20 at least generally in a forward direction 22indicated by an arrow. While the present example is framed in terms ofthe use of a boring tool as the inground tool and may be referred to assuch, it should be appreciated that the discussions apply to anysuitable form of inground tool including but not limited to a reamingtool, a tension monitoring tool for use during a pullback operation inwhich a utility or casing can be installed, a mapping tool for use inmapping the path of the borehole, for example, using an inertialguidance unit and downhole pressure monitoring. In the operation of aboring tool, it is generally desirable to monitor based on the advanceof the drill string whereas in other operations such as a pullbackoperation, monitoring can be performed responsive to retraction of thedrill string.

With continuing reference to FIG. 1, drill string 16 is partially shownand is segmented, being made up of a plurality of removably attachable,individual drill pipe sections some of which are indicated as 1, 2, n−1and n, having a section or segment length and a wall thickness. Thedrill pipe sections may be referred to interchangeably as drill rodshaving a rod length. During operation of the drill rig, one drill pipesection at a time can be added to the drill string and pushed into theground by the drill rig using a movable carriage 30 in order to advancethe inground tool. Drill rig 14 can include a suitable monitoringarrangement 32 for measuring movement of the drill string into theground such as is described, for example, in U.S. Pat. No. 6,035,951(hereinafter the '951 patent), entitled SYSTEMS, ARRANGEMENTS ANDASSOCIATED METHODS FOR TRACKING AND/OR GUIDING AN UNDERGROUND BORINGTOOL, which is commonly owned with the present application and herebyincorporated by reference.

Each drill pipe section defines a through opening 34 (one of which isindicated) extending between opposing ends of the pipe section. Thedrill pipe sections can be fitted with what are commonly referred to asbox and pin fittings such that each end of a given drill pipe sectioncan threadingly engage an adjacent end of another drill pipe section inthe drill string in a well known manner. Once the drill pipe sectionsare engaged to make up the drill string, the through openings ofadjacent ones of the drill pipe sections align to form an overallpathway 36 that is indicated by an arrow. Pathway 36 can provide for apressurized flow of drilling fluid or mud, consistent with the directionof arrow 36, from the drill rig to the drill head, as will be furtherdescribed.

The location of the boring tool within region 12 as well as theunderground path followed by the boring tool may be established anddisplayed at drill rig 14, for example, on a console 42 using a display44. The console can include a processing arrangement 46 and a controlactuator arrangement 47. In some embodiments, control and monitoring ofoperational parameters can be automated.

Boring tool 20 can include a drill head 50 having an angled face for usein steering based on roll orientation. That is, the drill head whenpushed ahead without rotation will generally be deflected on the basisof the roll orientation of its angled face. On the other hand, the drillhead can generally be caused to travel in a straight line by rotatingthe drill string as it is pushed, as indicated by a double-headed arrow51. Of course, predictable steering is premised upon suitable soilconditions. It is noted that the aforementioned drilling fluid can beemitted as jets 52 under high pressure for purposes of cutting throughthe ground immediately in front of the drill head as well as providingfor cooling and lubrication of the drill head. Boring tool 20 includesan inground housing 54 that receives an electronics package 56. Theinground housing is configured to provide for the flow of drilling fluidto drill head 50 around the electronics package. For example, theelectronics package can include a cylindrical housing configuration thatis supported in a centered manner within housing 54. Drill head 50 caninclude a box fitting that receives a pin fitting of inground housing54. An opposing end of the inground housing can include a box fittingthat receives a pin fitting of an isolator 60. An opposing end ofisolator 60 can include a box fitting that receives a pin fitting. Forpurposes of the discussions herein and the appended claims, the isolatorand boring tool can be considered as part of the drill string so as todefine a distal, inground end of the drill string. It is noted that thebox and pin fittings of the drill head, the inground housing and theisolator can be the same box and pin fittings as those found on thedrill pipe sections of the drill string for facilitating removableattachment of the drill pipe sections to one another in forming thedrill string. Inground electronics package 56 can include a drill stringtransceiver 64 and a locating transceiver 65. Further details withrespect to the drill string transceiver will be provided at appropriatepoints hereinafter. Locating transceiver 65, in some embodiments, cantransmit a ground penetrating signal 66 such as, for example, a dipolelocating signal and can receive an electromagnetic signal that isgenerated by other inground components as will be described at anappropriate point below. In other embodiments, transceiver 65 can bereplaced by a transmitter or may not be needed. The present exampleassumes that electromagnetic signal 66 is a locating signal in the formof a dipole signal for descriptive purposes. Accordingly,electromagnetic signal 66 may be referred to as a locating signal. Itshould be appreciated that the locating signal can be modulated like anyother electromagnetic signal and that the modulation data is thereafterrecoverable from the signal. The locating functionality of the signaldepends, at least in part, on the characteristic shape of the flux fieldand its signal strength rather than its ability to carry modulation.Thus, modulation is not required. Information regarding certainparameters of the boring tool such as, for example, pitch and roll(orientation parameters), temperature, drilling fluid pressure andannular pressure surrounding the boring tool can be measured by asuitable sensor arrangement 68 located within the boring tool which mayinclude, for example, a pitch sensor, a roll sensor, a temperaturesensor, an AC field sensor for sensing proximity of 50/60 Hz utilitylines and any other sensors that are desired such as, for example, a DCmagnetic field sensor for sensing yaw orientation (a tri-axialmagnetometer, with a three axis accelerometer to form a electroniccompass to measure yaw orientation) and one or more pressure sensors.Drill string transceiver 64 can include a processor that is interfacedas necessary with sensor arrangement 68 and locating transceiver 65. Insome embodiments, one or more accelerometers can be used to measureorientation parameters such as pitch and roll orientation. A battery(not shown) can be provided within the housing for providing electricalpower.

A portable locator 80 can be used to detect electromagnetic signal 66.One suitable and highly advanced portable locater is described in U.S.Pat. No. 6,496,008, entitled FLUX PLANE LOCATING IN AN UNDERGROUNDDRILLING SYSTEM, which is commonly owned with the present applicationand is incorporated herein by reference in its entirety. As mentionedabove, the present descriptions apply to a variety of ingroundoperations and are not intended as being limiting, although theframework of horizontal directional drilling has been employed fordescriptive purposes. As discussed above, electromagnetic signal 66 cancarry information including orientation parameters such as, for example,pitch and roll. Other information can also be carried by theelectromagnetic signal. Such information can include, by way of example,parameters that can be measured proximate to or internal to the boringtool including temperatures, pressures and voltages such as a battery orpower supply voltage. Locator 80 includes an electronics package 82. Itis noted that the electronics package is interfaced for electricalcommunication with the various components of the locator and can performdata processing. Information of interest can be modulated onelectromagnetic signal 66 in any suitable manner and transmitted tolocator 80 and/or an antenna 84 at the drill rig, although this is notrequired. Any suitable form of modulation may be used either currentlyavailable or yet to be developed. Examples of currently available andsuitable types of modulation include amplitude modulation, frequencymodulation, phase modulation and variants thereof. Any parameter ofinterest in relation to drilling such as, for example, pitch may bedisplayed on display 44 and/or on a display 86 of locator 80 asrecovered from the locating signal. Drill rig 14 can transmit atelemetry signal 98 that can be received by locator 80. The telemetrycomponents provide for bidirectional signaling between the drill rig andlocator 80. As one example of such signaling, based on status providedby drill rig monitoring unit 32, the drill rig can transmit anindication that the drill string is in a stationary state because adrill pipe section is being added to or removed from the drill string.

Still referring to FIG. 1, an electrical cable 100 can extend frominground electronics package 56 such that any sensed value or parameterrelating to the operation of the inground tool can be electricallytransmitted on this cable. One of ordinary skill in the art willappreciate that what is commonly referred to as a “wire-in-pipe” can beused to transfer signals to the drill rig. The term wire-in-pipe refersto an electrical cable that is generally housed within interiorpassageway 36 that is formed by the drill string. In accordance with thepresent disclosure, however, cable 100 extends to inground isolator 60,as will be further described.

Attention is now directed to FIG. 2 in conjunction with FIG. 1. FIG. 2is a diagrammatic perspective view which illustrates an embodiment ofisolator 60 in its assembled form. The assembly includes a pin endhousing 200 having a pin fitting 202 defining a through passage fromwhich cable 100 can extend for external electrical connection. A box endhousing 210 defines a box fitting 212. As discussed above, pin fitting202 and box fitting 212 can match the fittings on drill pipe sectionsthat make up drill string 16 such that the isolator can be inserted inany desired joint in the drill string. As will be seen, the isolatorprovides electrical isolation of the pin end housing from the box endhousing.

Attention is now directed to FIGS. 3 and 4, in conjunction with FIG. 2.FIG. 3 is a diagrammatic exploded view of isolator 60 as seen from pinhousing end 200, while FIG. 4 is a diagrammatic exploded view of theisolator as seen from box housing end 210. It should be appreciated thatthreads have been shown no more than diagrammatically, if at all, on thepin and box fittings of the various figures as well as on othercomponents, but are understood to be present and such threadedconnections are well-known. The isolator further includes a drive doghousing 220 that engages each of pin housing end 200 and box housing end210 with the drive dog housing electrically coupled to the pin housingin the overall assembly. The pin housing end, box housing end and drivedog housing in the present embodiment, as well as embodiments yet to bedescribed, are generally formed from suitable high strength materialssuch as, for example, 4340, 4140, 4142 as well as 15-15HS or Monel K500(wherein the latter two are non-magnetic high strength alloys), sincethese components are subjected to the potentially hostile downholeenvironment as well as relatively extreme force loads during an ingroundoperation. Material selection can be based, at least in part, on theperformance characteristics of typical drill pipe sections. Box endhousing 210 includes an extension shaft 222 that supports a sealing ring226 and a spacer ring 228 in a spaced apart relationship. The sealingring and spacer ring are formed from a suitable electrically insulatingmaterial such as, for example, Delrin Acetal Copolymer, although anysuitable material can be used. O-ring grooves 230 can be formed in theexterior surfaces, as seen, as well as the interior surfaces (shown in afigure yet to be described) of the sealing ring and spacer ring. In thisregard, it should be appreciated that the isolator defines an overallthrough passage 232 such that a fluid such as drilling fluid or mud cantransit through the isolator to flow through the drill string. Extensionshaft 222 is receivable in the through passage of drive dog housing 220.An interior surface 238 (FIG. 3) of a free end of extension shaft 222can be threaded to engage a threaded end 240 of a clamp nut 242 afterinstallation of the extension shaft. The clamp nut defines a centralpassage 244 to provide for the flow of drilling fluid therethrough.Threads have not been illustrated on the clamp nut but are understood tobe present. As will be see in a subsequent figure, the drive dog housingcan define an endwall that confronts a shoulder 246 (FIG. 4) of theclamp nut. Thus, the clamp nut can draw extension shaft 222 into thethrough passage of the drive dog housing to retain the box end housing.The latter can include a peripheral flange 250 having a peripheralsidewall configuration 254 (FIG. 3) facing drive dog housing 220. Aconfronting end of the drive dog housing defines a peripheral endwall260 (best seen in FIG. 4) and which will be further described below.

Attention is now directed to FIG. 5 in conjunction with FIGS. 2-4. Theformer is a diagrammatic perspective view which illustrates box endhousing 210 and drive dog housing 220 in an operational relationshipsuch that peripheral sidewall configuration 254 of the box end housingis in a confronting relationship with peripheral endwall 260 of thedrive dog housing. This confronting relationship serves to define aplurality of pockets 264 (one of which is designated) between opposingshoulders 266 and 268 of box end housing 210 and drive dog housing 220,respectively. In the present embodiment, shoulders 266 and 268 are atleast generally cylindrical in configuration for purposes of capturing agroup of electrical isolators 270 therebetween. Each isolator 270includes a sidewall configuration that is complementary to the shape ofshoulders 266 and 268 and is therefore cylindrical in the presentembodiment. Further, each isolator 270 can include opposing end surfacesthat can be at least generally planar. As seen in FIGS. 2 and 3, box endhousing 210 provides a floor 274 for each pocket 264 such that an endsurface of each isolator 270 is supported or captured against floor 274.With isolators arranged as shown in FIG. 5, a sleeve 280 (FIGS. 2-4) canbe received on the box end housing such that tabs 282 (FIG. 2) projectover an outward facing end surface of each isolator 270 to retain theisolators in their associated pockets. Sleeve 280 can be retained inposition, for example, using a roll pin 286 that is receivable in anaperture 288 such that an intermediate portion of the roll pin isreceived in an annular groove.

Although not visible in the view of FIG. 5, it should be appreciatedthat clamp nut 242 is installed in a through passage 298 of the drivedog housing to engage extension 222 of the box end housing in a way thatretains the drive dog housing and the box end housing in the illustratedoperational relationship. Accordingly, isolators 270 are supportedhaving their elongation axes extending at least generally radially withrespect to the centerline or elongation axis of the overall assembly. Aswill be further discussed, the sidewalls of isolators 270, which arecylindrical in the present embodiment, are subjected to compressiveforce responsive to a push force 300 (indicated by an arrow in variousfigures) that is applied by the drill rig via the drill string.Likewise, rotation of the drill string applies compressive force to thesidewalls of isolators 270.

In view of the foregoing discussions, it should be appreciated thatisolators 270 can be subjected to very high compressive loading.Accordingly, a suitable material is needed in order to endure suchcompression. Suitable materials can include ceramic materials that areeither currently available or yet to be developed. By way ofnon-limiting example, one suitable ceramic material is toughenedZirconia. It is of interest that, while such ceramic materials are veryresistant to compressive forces, they are not generally as well suitedto tension loading. In the instance of toughened Zirconia, thecompressive strength is approximately 270,000 to 700,000 pounds persquare inch whereas the flexural strength is only approximately 58,000to 90,000 pounds per square inch. For purposes of comparison, theflexural strength of high strength steel such as, for example, 4340steel is approximately 175,000 pounds per square inch. It should alreadybe appreciated that, while drive dog housing 220 and box end housing 210apply compressive forces to isolators 270 responsive to both push androtation of the drill string, the assembly is incapable of subjectingisolators 270 to tension, as will be further described.

Referring to FIGS. 2-5 and as described above, clamp nut 242 can beconfigured to threadingly engage extension 222 of box end housing 210.In doing so, the clamp nut is housed within through passage 298 (FIG. 5)of the drive dog housing. As seen in FIG. 4, shoulder 246 of clamp nut242 defines a plurality of apertures 310, several of which areexplicitly designated. Another group or set of isolators, severalindividual ones of which are designated by the reference number 320(FIGS. 2 and 3), is supported with each one of this set of isolatorsreceived in a corresponding one of apertures 310 of the clamp nut. Inthe present embodiment, each isolator 320 can include at least generallyplanar end surfaces that are adjoined by a peripheral sidewall that canbe cylindrical in configuration, although this is not a requirement. Inan operational assembly, isolators 320 are captured between clamp nut242 and an endwall 324 (FIG. 5) of drive dog housing 220 having anelongation axis of each isolator 320 at least generally in a parallelalignment with the elongation axis of the overall assembly. It should beappreciated that the outward end surfaces of isolators 320 are slidinglyengaged against endwall 324. The discussions above with respect tomaterial selection for isolators 270 is also applicable with respect tomaterial selection for isolators 320. The latter can therefore be formedfrom suitable electrically insulating materials including ceramicmaterials that are either currently available or yet to be developed. Byway of non-limiting example, one suitable ceramic material is toughenedZirconia. It should be appreciated, at this juncture, that isolators320, like isolators 270, are not subjected to tensile forces duringoperation as a result of the manner in which they are supported by theisolator. Isolators 270 and 320 are not limited to the cylindricalconfiguration that has been illustrated. Any suitable shape can beutilized with appropriate modifications to support surfaces. Suitableshapes for use as isolators 270 can be selected from a wide range ofgeometric shapes such as, for example, spherical. Combinations of wellknown shapes can be used as well. Suitable shapes for use as isolators270 can likewise be selected from a wide variety of well-known geometricshapes or combinations of such shapes generally so long as at least onegenerally flat surface is provided for engaging endface 324 of the drivedog housing. For example, isolators 270 can be spherical with theexception of a flat for purposes of engaging endface 324. Duringinstallation, clamp nut 242 can be torqued to a significant value suchas, for example, 2500 foot-pounds to apply compressive force toisolators 320 as well as isolators 270 such that a compressive preloadis applied to all of the isolators. The compressive preload is appliedcompressively to opposing ends of the drive dog housing and results in apreload tension force in extension 222 that is complementary to thecompressive preload. In other words, the compressive preload attempts tostretch extension 222 responsive to the drive dog housing beingcompressed between peripheral flange 250 and clamp nut 242. The amountof compressive force, on an individual one of the electrical isolatorscan be based on the amount of retraction and/or thrust (push and/orpull) force that any given drill rig is capable of generating, as willbe further discussed.

Referring to FIGS. 2-4, electrical cable 100 can be installed onto clampnut 242 by receiving a fitting 340 into an aperture 342 that is definedby the clamp nut. In an embodiment, cable 100 can be a coaxial cable. Anelectrical conductor 344 of the cable can be clamped in position using alocking screw 346 which forms an electrical connection between conductor344 and the clamp nut. Pin end housing 200 can then be installed ontodrive dog housing 220 using threaded engagement with an end 348 of thedrive dog housing and with cable 100 extending through the centralpassage of the pin end housing such that the drive dog housing and thepin end housing are in electrical contact, however, the clamp nut andbox end housing are electrically isolated from the drive dog housing bysealing ring 226, spacer ring 228, isolators 270 and isolators 320.Accordingly, an electrically isolating break is formed in the drillstring through the cooperation of these insulating elements. At the sametime, the pin end housing can engage a downhole portion of the drillstring and maintain electrical communication with the drive dog housing.Cable 100 can readily be accessed or replaced in the isolator byremoving pin end housing 200.

FIG. 6 is a diagrammatic cut-away view, in elevation, that illustratesthe present embodiment of isolator 60, as assembled, and installed aspart of a drill string having an uphole portion 400 and a downholeportion 402. For purposes of this disclosure, the downhole portion ofthe drill string can comprise any suitable inground housing 406 such asa drill head housing and/or one or more intervening drill pipe sections(not shown) that connect isolator 60 to an inground housing 406. In thepresent example, the inground housing is a drill head or boring tool.Cable 100 can extend within the through passage of the drill string toelectronics package 56 for electrical communication with drill stringtransceiver 64 via electrical conductor 344 of cable 100. As discussedabove, drilling fluid can flow around the electronics package to reachan inground distal end of the drill string such as a drill head.Conductor 344 is electrically connected, at an opposing end, to a firstterminal of transceiver 64 while a second, opposing terminal of thetransceiver is electrically connected to the inground end of the drillstring as diagrammatically indicated by a line 410. That is, line 410 iselectrically connected to inground housing 54 in the present examplewhich is representative of any suitable electrical connection todownhole portion 402 of the drill string. Accordingly, drill stringtransceiver 64, diagrammatically shown as a signal receiving and signalgenerating source, is electrically connected or bridged across anelectrically isolating break or gap in the drill string, formed byinground isolator 60, such that uphole portion 400 serves as anelectrical conductor that leads directly to the drill rig while downholeportion 402 provides a return path to the surrounding earth for thesignal.

Having described isolator 60 in detail above with respect to itsstructure, attention is now directed to the method by which the isolatoroperates when in service as part of a drill string in terms of handlingpush, pull and rotational forces. Referring to FIG. 6, push force 300 isillustrated by an arrow. When the isolator receives such a push forcefrom the uphole portion of the drill string, box end housing 210initially receives the force which is immediately transferred to drivedog housing 220 by compressing isolators 270. As described above, drivedog housing 220 is coupled, for example, by threaded engagement directlyto pin end housing 200 to transfer the push force to downhole portion402 of the drill string. It is noted that push force 300 does not applya compressive force to isolators 320 but rather actually decreases anycompressive preload (if present) on these isolators that can be appliedby clamp nut 242. During a pull force, opposite arrow 300, upholeportion 400 of the drill string pulls on box end housing 210 and onclamp nut 242 which is in threaded engagement with the box end housing.This results in isolators 320 being urged against end surface 324 (FIG.5) of drive dog housing 220 such that the drive dog housing is forced inthe uphole direction. At the same time, the pull force does not applyadditional compressive force to isolators 270, but rather decreasescompressive preload, if present. Because drive dog housing 220 is inthreaded engagement with pin end housing 200, the latter also moves inthe uphole direction which, therefore, pulls downhole portion 402 of thedrill string in the uphole direction. Rotational torque from upholeportion 400 of the drill string is received by box end housing 210 in away that results in compressing alternating ones of isolators 270 (seeFIG. 5), as described above. Thus, a group of three isolators 270, whichis less than the total number of six isolators 270, can be subject tothe rotational torque. Threaded engagement between drive dog housing 220and pin end housing 200 causes the latter to co-rotate with the drivedog housing which, in turn, rotates the downhole portion of the drillstring. In any mode of operation, isolators 270 and 320 are not subjectto tensile loading. Thus, the material characteristic of these isolatorswhich is relevant to operation is compressive strength while tensilestrength or lack thereof is essentially irrelevant.

FIG. 7 is a diagrammatic view, in perspective, which illustratesinground tool 20 in the form of a boring tool having drill head 50 forpurposes of still further description. In this embodiment, ingroundhousing 54 includes slots 420 for purposes of emitting signal 66 fromtransceiver 64 (FIG. 1). Isolator 60, serving as an example of asuitable embodiment, is removably attached to inground housing 54,comprising downhole portion 402 of the drill string, and which is itselfremovably attached to uphole portion 400 of the drill string.

FIG. 8 is a diagrammatic view, in perspective, which illustratesinground tool 20 in the form of a reaming tool including a reamer 424that is removably attached to one end of inground housing 54 to serve asdownhole portion 402 of the drill string. Housing 54 and isolator 60 areotherwise provided in this embodiment in the same manner as in FIG. 7.The reaming tool is pulled in an uphole direction 426, which isindicated by an arrow, for purposes of enlarging a borehole as thereaming tool is pulled toward the drill rig by the drill string. Anopposing end of the reaming tool is attached to one end of a tensionmonitoring arrangement 430. An opposing end of the tension monitoringarrangement can be attached to a utility (not shown) that is to bepulled through the enlarged borehole for installation of the utility inthe borehole. Tension monitoring arrangement 430 measures the pullforces that are applied to the utility during the reaming operation. Onesuitable and highly advantageous tension monitoring arrangement isdescribed in U.S. Pat. No. 5,961,252 which is commonly owned with thepresent application and incorporated herein by reference in itsentirety. Tension monitoring arrangement 430 can transmit anelectromagnetic signal 434 upon which tension monitoring andrelated/other data can be modulated. Signal 434 can be received bytransceiver 65 (FIG. 1) such that corresponding data can be placed uponthe drill string using isolator 60 for transmission to the drill rig. Itshould be appreciated that a wireless signal can be received from anyform of inground tool by transceiver 65 and that the present embodiment,which describes a tension monitoring arrangement, is not intended aslimiting. For example, a mapping arrangement can be used in anotherembodiment in place of the tension monitoring arrangement. Such amapping arrangement can operate, for example, using an inertialnavigation system (INS).

FIG. 9 is a block diagram which illustrates an embodiment of electronicssection 56 in further detail. Section 56 can include an inground digitalsignal processor 510 which can facilitate all of the functionality oftransceiver 64 of FIGS. 1 and 6. Sensor section 68 is electricallyconnected to digital signal processor 510 via an analog to digitalconverter (ADC) 512. Any suitable combination of sensors can be providedfor a given application and can be selected, for example, from anaccelerometer 520, a magnetometer 522, a temperature sensor 524 and apressure sensor 526 which can sense the pressure of drilling fluid priorto being emitted from the drill string and/or within the annular regionsurrounding the downhole portion of the drill string. Isolator 60 isdiagrammatically shown as separating uphole portion 400 of the drillstring from downhole portion 402 of the drill string for use in one orboth of a transmit mode, in which data is coupled onto the drill string,and a receive mode in which data is recovered from the drill string. Theelectronics section is connected across the electricallyinsulating/isolating break formed by the isolator by a first lead 528 aand a second lead 528 b which can be referred to collectively by thereference number 528. For the transmit mode, an antenna driver section530 is used which is electrically connected between inground digitalsignal processor 510 and leads 528 to directly drive the drill string.Generally, the data that can be coupled into the drill string can bemodulated using a frequency that is different from any frequency that isused to drive a dipole antenna 540 that can emit aforedescribed signal66 (FIG. 1) in order to avoid interference. When antenna driver 530 isoff, an On/Off Switcher (SW) 550 can selectively connect leads 528 to aband pass filter (BPF) 552 having a center frequency that corresponds tothe center frequency of the data signal that is received from the drillstring. BPF 552 is, in turn, connected to an analog to digital converter(ADC) 554 which is itself connected to digital signal processing section510. Recovery of the modulated data in the digital signal processingsection can be readily configured by one having ordinary skill in theart in view of the particular form of modulation that is employed.

Still referring to FIG. 9, dipole antenna 540 can be connected for usein one or both of a transmit mode, in which signal 66 is transmittedinto the surrounding earth, and a receive mode in which anelectromagnetic signal such as, for example, signal 434 of FIG. 8 isreceived. For the transmit mode, an antenna driver section 560 is usedwhich is electrically connected between inground digital signalprocessor 510 and dipole antenna 540 to drive the antenna. Again, thefrequency of signal 66 will generally be sufficiently different from thefrequency of the drill string signal to avoid interference therebetween.When antenna driver 560 is off, an On/Off Switcher (SW) 570 canselectively connect dipole antenna 540 to a band pass filter (BPF) 572having a center frequency that corresponds to the center frequency ofthe data signal that is received from the dipole antenna. BPF 572 is, inturn, connected to an analog to digital converter (ADC) 574 which isitself connected to digital signal processing section 510. Transceiverelectronics for the digital signal processing section can be readilyconfigured in many suitable embodiments by one having ordinary skill inthe art in view of the particular form or forms of modulation employedand in view of this overall disclosure. The design show in FIG. 9 can bemodified in any suitable manner in view of the teachings that have beenbrought to light herein.

Referring to FIGS. 1 and 10, the latter is a block diagram of componentsthat can make up an embodiment of an aboveground transceiverarrangement, generally indicated by the reference number 600, that iscoupled to drill string 16. An aboveground current transformer 602 ispositioned, for example, on drill rig 14 for coupling and/or recoveringsignals to and/or from drill string 16. Current transformer 602 can beelectrically connected for use in one or both of a transmit mode, inwhich data is modulated onto the drill string, and a receive mode inwhich modulated data is recovered from the drill string. A transceiverelectronics package 606 is connected to the current transformer and canbe battery powered. For the transmit mode, an antenna driver section 610is used which is electrically connected between an aboveground digitalsignal processor 620 and current transformer 602 to drive the currenttransformer. Again, the data that can be coupled into the drill stringcan be modulated using a frequency that is different from the frequencythat is used to drive dipole antenna 540 in inground housing 54 (FIG. 1)in order to avoid interference as well as being different from thefrequency at which isolator 60 (FIG. 9) drives a signal onto theinground end of the drill string. When antenna driver 610 is off, anOn/Off Switcher (SW) 620 can selectively connect current transformer 602to a band pass filter (BPF) 622 having a center frequency thatcorresponds to the center frequency of the data signal that is receivedfrom the drill string. BPF 622 is, in turn, connected to an analog todigital converter (ADC) 630 which is itself connected to digital signalprocessing section 632. It should be appreciated that digital signalprocessing section 632 and related components can form part ofprocessing arrangement 46 (shown using a dashed line) of the drill rigor be connected thereto on a suitable interface 634. Transceiver 606 cansend commands to the inground tool for a variety of purposes such as,for example, to control transmission power, select a modulationfrequency, change data format (e.g., lower the baud rate to increasedecoding range) and the like. Transceiver electronics for the digitalsignal processing section can be readily configured in many suitableembodiments by one having ordinary skill in the art in view of theparticular form or forms of modulation employed and in view of thisoverall disclosure.

Still referring to FIGS. 1 and 10, in a repeater embodiment, anotheringround isolator arrangement 640 (shown within a dashed box), canreplace current transformer 602 along with another instance of ingroundhousing 54. Arrangement 640 can include any suitable embodiment ofinground isolator according to the present disclosure including anotherinstance of isolator 60. The latter, in this arrangement, is connectedto transceiver 606 (FIG. 10) and is inserted as a unit into one of thejoints of the drill string to serve in the manner of a repeater, by wayof example, 1000 feet from the inground tool. Thus, a section 400′ ofthe drill string can connect the isolator to the drill rig while asection 402′ of the drill string serves as an intermediate section ofthe drill string between isolator arrangement 640 and isolator 60 at theinground tool. The repeater unit can be inserted, for example, in thejoint formed between drill pipe sections 1 and 2 in FIG. 1. The ingroundhousing, for use in a repeater application, can include a box fitting atone end and a pin fitting at an opposing end. Of course, one of ordinaryskill in the art will recognize that box to pin fitting adapters arewell known and readily available. In another embodiment, isolatorarrangement 640 can be inserted into a joint with the repeaterelectronics housed in a pressure barrel that can be supported bycentralizers within the through passage of an adjacent drill pipesection. In yet another embodiment, the repeater electronics can beplaced in an end loaded or side loaded housing and inserted into thedrill string with electrical communication to the isolator. Such end orside loaded housings can include passages that allow for the flow ofdrilling fluid therethrough. In any of these embodiments, of course, therepeater electronics can be electrically connected to the isolator in amanner that is consistent with the descriptions above. In order to avoidsignal interference and by way of non-limiting example, a repeater canpick up the signal originating from the inground tool or anotherrepeater at one carrier frequency and the repeater electronics canretransmit the signal up the drill string at a different carrierfrequency in order to render the signals distinguishable from oneanother. As another example, suitable modulation can be used to make thesignals distinguishable. Thus, the repeater electronics package can behoused in any suitable manner in electrical communication with thesignal coupling arrangement of the isolator for producing a repeatersignal based on the received data signal, but which is distinguishablefrom the received data signal.

Attention is now directed to FIG. 11 which illustrates anotherembodiment of an inground isolator, in accordance with the presentdisclosure, generally indicated by the reference number 60′, in adiagrammatic perspective view. It is noted that isolator 60′ can be usedin a manner that is identical to that of aforedescribed isolator 60.Like reference numbers have been applied to components and features thatare shared by isolators 60 and 60′. In instances of the use of amodified component or feature, a prime (′) mark has been appended to thepreviously applied reference number.

Referring collectively to FIGS. 11-13, details will now be provided withrespect to embodiment 60′ of the isolator. FIGS. 12 and 13 are explodeddiagrammatic views, in perspective, taken from different angles in orderto illustrate details of the present embodiment. As seen in FIG. 12, boxend housing 210′ includes a peripheral flange 250′ having a peripheralsidewall configuration 254′ which defines a plurality of recesses 700.In the present embodiment, each recess is defined as a concave sphericalsurface that is generally no more than one-half (a hemisphere) of anoverall spherical outline. Each recess 700 is configured to partiallyreceive one of a first plurality of electrical isolators 710, eachelectrical isolator being spherical in form in the present embodiment.As seen in FIG. 13, a peripheral endwall 260′ of drive dog housing 220′defines a corresponding plurality of recesses 714 that can have the sameshape as recesses 700. When isolator 60′ is assembled, as in the view ofFIG. 11, electrical isolators 710 are captured between drive dog housing220′ and box end housing 210′ with each electrical isolator 710partially received in one recess 700 and partially received in acooperating and confronting recess 714. While twelve electricalisolators 710 and cooperating recesses are used in the presentembodiment.

Still referring to FIGS. 11-13, a second plurality of electricalisolators 730 is positioned between an endface 324′ of drive dog housing220′ (FIG. 12) and a support ring 734. In an embodiment, electricalisolators 730 can be identical to electrical isolators 710 although thisis not required. In the present embodiment, eight electrical isolators730 have been used, however, this is not a requirement and any suitablenumber of these electrical isolators can be used. Each electricalisolator 730 is partially receivable in one of a plurality of recesses738, defined in endface 324′, and partially receivable in one of aplurality of cooperating recesses 740 (FIG. 13), defined by support ring734. The latter is itself received upon threaded end 240 of clamp nut242′ such that the support ring can rotate relative to the clamp nut.Assembly can be accomplished, by way of non-limiting example, byinstalling drive dog housing 220′ on extension shaft 222 with sealingring 226 and spacer ring 228 in place to capture electrical isolators710 between the box end housing and the drive dog housing. Shaft 240 ofclamp nut 242′ can be installed through ring 734 and through theinternal cavity of the drive dog housing such that the threads ofthreaded shaft 240 engage cooperating threads formed on interior surface238 of box end housing 210′ to capture electrical isolators 730 inconfronting pairs of recesses 738 and 740 of the drive dog housing andsupport ring, respectively. Clamp nut 242′ can then be torqued to asuitable value such as, for example, 2500 foot-pounds, by way ofnon-limiting example, to apply compressive force to electrical isolators710 as well as electrical isolators 730 such that a compressive preloadis applied to all of the electrical isolators. The amount of compressivepreload force, on an individual one of the electrical isolators, can bebased on the amount of retraction and/or thrust (push and/or pull) forcethat any given drill rig is capable of generating, as will be furtherdiscussed. The compressive preload is applied compressively to opposingends of the drive dog housing and again results in a preload tensionforce in extension 222 that is complementary to the compressive preload.In other words, the compressive preload attempts to stretch extension222 because drive dog housing 220′ is compressed between peripheralflange 250′ and clamp nut 242 via support ring 734. Cable 100 can thenbe installed using locking screw 346 and routed through the interior ofpin end housing 200′. The pin end housing can then be torqued ontothreaded end 348 of drive dog housing 220′, although any suitable formof attachment can be used.

In view of the foregoing, drive dog housing 220′ and pin end housing200′ are in electrical contact, however, clamp nut 242′ and box endhousing 210′ are electrically isolated from drive dog housing 220′ bysealing ring 226, spacer ring 228, electrical isolators 710 andelectrical isolators 730. Accordingly, an electrically isolating breakis formed in the drill string through the cooperation of theseinsulating elements. At the same time, the pin end housing canphysically engage a downhole portion of the drill string and maintainelectrical communication with the drive dog housing. Cable 100 canreadily be accessed or replaced in the isolator by removing pin endhousing 200′.

During operation, push force 300 can be applied in a direction that isindicated by an arrow. When isolator 60′ receives such a push force fromthe uphole portion of the drill string, box end housing 210′ initiallyreceives the force which is immediately transferred to drive dog housing220′ by compressing electrical isolators 710. As described above, drivedog housing 220′ is coupled, for example, by threaded engagementdirectly to pin end housing 200′ to transfer the push force to downholeportion 402 (FIG. 6) of the drill string. As in embodiment 60 withrespect to electrical isolators 274, push force 300 does not apply acompressive force to electrical isolators 730 but rather actuallydecreases any compressive preload on these electrical isolators that canbe applied by clamp nut 242′. During a pull force, opposite arrow 300,uphole portion 400 of the drill string pulls on box end housing 210′ andon clamp nut 242′ which is in threaded engagement with the box endhousing. This results in electrical isolators 730 being urged againstend surface 324′ (FIG. 12) of drive dog housing 220′ by support ring 734such that the drive dog housing is forced in the uphole direction.Because drive dog housing 220′ is in threaded engagement with pin endhousing 200′, the latter also moves in the uphole direction which,therefore, pulls downhole portion 402 of the drill string in the upholedirection. Rotational torque from uphole portion 400 of the drillstring, responsive to either direction of rotation, is received by boxend housing 210′ in a way that results in the application offlexural/shear stress to electrical isolators 710. On the other hand,electrical isolators 730 are not subject to such flexural/shear stressdue to rotational torque at least for the reason that support ring 734can rotate relative to clamp nut 242′.

As noted above, electrical isolators 710 and 730 can be formed from thesame material or from different materials either currently available oryet to be developed. Further, in some embodiments, electrical isolators710 can be formed from different materials than electrical isolators730. Suitable materials, by way of non-limiting example, include siliconnitride and transformation toughened zirconia. Empirical testingperformed by Applicants has demonstrated that an arrangement of onlythree spherical silicon nitride electrical isolators can be capable ofwithstanding three times the rated torque of a typical drill pipesection. In other embodiments, either or both groups of electricalisolators 710 and 730 can include peripheral outlines that can be otherthan spherical. In such embodiments, the recesses that capture theelectrical isolators can include a complementary shape. By way ofnon-limiting example, other suitable shapes can comprise a wide range ofgeometric shapes including but not limited to elongated such ascylindrical and ortho-rectangular. Further, the layout of the electricalisolators can be changed in any suitable manner. With regard to layout,for example, concentric rings of electrical isolators can be provided.

Referring to FIG. 14, an inground tool, produced according to thepresent disclosure is shown in a cut-away diagrammatic perspective viewand is generally indicated by the reference number 800. FIGS. 15 and 16illustrate inground tool 800 in exploded perspective views for furtherillustrative purposes and are taken from appropriate perspectives toillustrate opposing ends of the various components. In the presentembodiment, the inground tool is a drill head or bit into whichelectrical isolation has been integrated. In particular, a drillhead 804can serve as the inground distal end of the drill string. The drill bitis located at one end of a drill housing 810 while an opposing end 814can be configured to engage drive dog housing 220′ in a manner that isconsistent with the engagement between pin end fitting 200′ and drivedog housing 220′ of FIGS. 11-13. For example, opposing end 814 canthreadingly engage the drive dog housing. Drill housing 810 can define acavity for receiving a suitable electronics package such as, forexample, previously described electronics package 56. The installedorientation and position of the electronics package can be established,for example, using a spring pin 812 (FIG. 15) that can pass throughcorresponding openings 814 a and 814 b in each of the drill housing andthe electronics package, respectively. Cable 100 can be received by theelectronics package, for example, by a pipe plug fitting 815 (FIGS. 15and 16). A cover 816 can be held in position by fasteners 820 to providefor installation and removal of electronics 56. One or more slots 420can provide for emitting signal 66 in a manner that is consistent withthe descriptions above and/or for receiving an electromagnetic signal824 (FIG. 14) from another source such as, for example, an above groundportable device. A mud channel 830 can conduct drilling mud past theelectronics package for emission from drill bit 804 in any suitablemanner.

In view of FIG. 14, another embodiment of an inground tool according tothe present disclosure can be based on the configuration of ingroundtool 60 of FIGS. 3 and 4, utilizing cylindrical or other suitably shapedelectrical isolators such as are seen in the subject figures. Inparticular, drill housing 810 of FIG. 14 can be affixed, for example, bythreading engagement to threaded end 348 of drive dog housing 220 inFIGS. 3 and 4.

Referring to FIGS. 2, 11 and 14, it should be understood that aninground tool such as, for example, the drill housing of FIG. 14 can beinstalled in place of the pin housing in either FIGS. 2 and 11, therebyforming the basis of an interchangeable system. As part of this system,when opposing drill pipe fittings are provided on the inground isolatorsas seen in FIGS. 2 and 11, the apparatus can be inserted into any jointin the drill string between otherwise adjacent drill rods to form partof the overall length of the drill string. Associated electronics can behoused in any suitable manner either external to the inground isolatoror internal thereto. For example, pin end housings 200 (FIG. 3) and 200′can be further elongated and configured to support any desiredelectronics package. Moreover, a selection of interchangeable fittingscan be provided including but not limited to a drill pipe fittingincluding a pin end housing and/or a box end housing, a drill head and areamer. Irrespective of the fitting that is used at any given time, itshould be appreciated that the various components of these assembliesthat cooperate to provide for electrical isolation can readily beaccessed for maintenance and/or repair purposes.

Attention is now directed to FIGS. 17 and 18 which illustrate aninground tool system produced according to the present disclosure andgenerally indicated by the reference number 900. FIG. 17 is adiagrammatic assembly view, in perspective, and FIG. 18 is adiagrammatic exploded view, in perspective. The inground tool system, inthe illustrated embodiment, supports a reamer 904 having a pull tab 908at one end that can be used to pull a utility through the ground. Ofcourse, a tension monitoring arrangement can be imposed between thereamer and the utility, for example, based on the embodiment of FIG. 8,as described above. Box end housing 210′ and drive dog housing 220′ canbe used along with associated components such as, for example,electrical isolators 710 and 730 in a manner that is consistent with thedescriptions above. In another embodiment, box end housing 210 and drivedog housing 220 of FIGS. 2-4 can be used along with associatedcomponents such as, for example, electrical isolators 270 and 320 in amanner that is consistent with the descriptions above relating to thesefigures. Accordingly, the reader is referred to the detailed discussionswhich appear above.

With continuing reference to FIGS. 17 and 18, an electronics housing 920can be removably attached to a given embodiment of the drive dog housingthat is in use such as, for example, drive dog housing 220′. Suchattachment, for example, can be by way of threaded engagement or by wayof any suitable mechanism. Housing 920 includes an elongated length andan opposing end 924 that defines a suitable fitting for engaging aninground tool such as, for example, reamer 904 to serve as an ingrounddistal end of the drill string. In the present embodiment, opposing end924 is a box end fitting and reamer 904 includes a pin end fitting 926.Housing 920 defines an interior cavity for receiving and supportingelectronics package 56 in a manner that is consistent with thedescriptions relating to FIGS. 14-15, although any suitable arrangementcan be used. A cover 816′ can be installed using a single fastener 820since this cover defines a projecting 930 that is initially receivablewithin a cooperating feature of housing 920. Installation of fastener820 then serves to maintain the cover in an installed position duringinground operations. The flow of drilling fluid can be supported using apassage that can be formed in the manner, for example, of passage 830 ofFIG. 14. It should be appreciated that reamer 904 can readily bereplaced by a different inground tool such as, for example, drill bit 50of FIG. 7.

The foregoing descriptions are not intended as being limiting withrespect to the specific forms and/or combinations of housings andelectrical isolators that have been utilized for purposes of forming anelectrically isolating break or gap in the drill string. In this regard,any suitable modifications for purposes of forming an electricallyisolating drill string gap are considered to be within the scope of thepresent disclosure so long as the teachings that have been brought tolight herein are being practiced. Accordingly, embodiments of aninterchangeable inground tool system have been provided which, in any ofits various forms, facilitates communication using the drill string asan electrical conductor while maintaining robust mechanical performancecharacteristics that measure up to or can even exceed the performancecharacteristics of the drill rods themselves which make up the drillstring. It is submitted that such a system, associated components andmethods have not been seen heretofore. The present disclosure issubmitted to sweep aside the limitations of prior art approaches thatattempt to provide an electrically isolating break in the drill stringby introducing what is, in effect, a weakened annular connection that isformed using an electrical insulator but which is nevertheless subjectto full operational loading or other prior art approaches that attemptto use relatively thin layers of insulating/dielectric material that aresubject to compromise by being worn through.

The foregoing description of the invention has been presented forpurposes of illustration and description. It is not intended to beexhaustive or to limit the invention to the precise form or formsdisclosed, and other embodiments, modifications and variations may bepossible in light of the above teachings wherein those of skill in theart will recognize certain modifications, permutations, additions andsub-combinations thereof.

What is claimed is:
 1. An apparatus for use in combination with a drill string that is electrically conductive and extends from an inground distal end, that includes an inground tool, to a drill rig, said apparatus comprising: a first group of electrical isolators and a second group of electrical isolators; and a housing that defines a through passage along a length thereof and said housing is configured to support the first group and the second group in a spaced apart relationship along said length and surrounding the through passage such that, responsive to the drill rig pushing on the drill string, a first one of the first and second groups is subject to a first compressive force and responsive to the drill rig pulling on the drill string the other one of the first and second groups is subject to a second compressive force without subjecting either of the first and second groups to a tension force during said pushing and pulling by the drill rig to form an electrically isolating break in the drill string.
 2. The apparatus of claim 1 wherein said housing is configured such that, responsive to the drill rig pushing on the drill string, a first one of the first and second groups is subject to the first compressive force without subjecting the second group to the first compressive force and, responsive to the drill rig pulling on the drill string, and responsive to the drill rig pulling on the drill string a second one of the first and second groups is subject to the second compressive force without subjecting the other one of the first and second groups to the second compressive force.
 3. The apparatus of claim 1 configured for insertion into the drill string to thereafter form part of an overall length of the drill string.
 4. The apparatus of claim 1 configured to form part of said inground tool.
 5. The apparatus of claim 1 configured to subject a selected one of the first and second groups of electrical isolators to an additional compressive force responsive to a rotational torque that is applied to the drill string by the drill rig.
 6. The apparatus of claim 5 wherein only the selected one of the first and second groups is subject to said further additional compressive force.
 7. The apparatus of claim 1 wherein the first group of electrical isolators and the second group of electrical isolators are formed from an identical material.
 8. The apparatus of claim 1 wherein the first insulating members and the second insulating members are a ceramic material.
 9. The apparatus of claim 8 wherein the ceramic material is selected as at least one of a toughened zirconia and a silicon nitride ceramic.
 10. The apparatus of claim 1 wherein each electrical isolator is spherical in configuration.
 11. The apparatus of claim 1 wherein said first group of electrical isolators comprises a plurality of elongated members and said housing captures the plurality of elongated members in a uniformly spaced apart distribution around a centerline of the housing.
 12. The apparatus of claim 11 wherein each one of the plurality of elongated members is a cylindrical member defining an elongation axis and said housing supports each one of the plurality of cylindrical members having said elongation axis at least approximately parallel to said centerline.
 13. The apparatus of claim 12 wherein each cylindrical member is formed having a solid core.
 14. The apparatus of claim 12 wherein the plurality of cylindrical members is subject to said second compressive force responsive to the drill rig pulling on the drill string.
 15. The apparatus of claim 14 wherein said second compressive force is applied to a pair of opposing end surfaces of each cylindrical member.
 16. The apparatus of claim 12 wherein said housing supports six of said cylindrical members.
 17. The apparatus of claim 1 wherein said second group of electrical isolators comprises a plurality of elongated members and said housing captures the plurality of elongated members in a uniformly spaced apart distribution around a centerline of the housing.
 18. The apparatus of claim 17 wherein each one of the plurality of elongated members is a cylindrical member defining an elongation axis and said housing supports each one of the plurality of cylindrical members having said elongation axis extending at least approximately radially from said centerline.
 19. The apparatus of claim 18 wherein the plurality of cylindrical members is subject to said first compressive force responsive to the drill rig pushing on the drill string.
 20. The apparatus of claim 19 wherein said compressive force is applied to opposing side margins of a cylindrical sidewall of each cylindrical member.
 21. The apparatus of claim 18 wherein said drill rig is configured to apply rotation to the drill string and the housing is configured to apply an additional compressive force to the cylindrical members for transferring the rotational torque to the inground tool.
 22. The apparatus of claim 21 wherein said additional compressive force is applied to a cylindrical sidewall of each cylindrical member.
 23. The apparatus of claim 19 wherein said housing supports six of said cylindrical members.
 24. The apparatus of claim 1 further comprising: said first group of electrical isolators comprises a first plurality of cylindrical members and said housing captures the first plurality of cylindrical members in a first uniformly spaced apart distribution around a centerline of the housing; and said second group of electrical isolators comprises a second plurality of cylindrical members and said housing captures the second plurality of cylindrical members in a second uniformly spaced apart distribution around the centerline of the housing.
 25. The apparatus of claim 24 wherein each one of said first plurality of cylindrical members defines an elongation axis that is supported at least approximately parallel to the centerline and each one of the second plurality of cylindrical members defines an elongation axis that is supported to extend at least approximately radially from said centerline.
 26. The apparatus of claim 1 wherein said housing includes a drive dog housing having (i) a first end configured to engage a first end fitting for fixed rotation as well as electrical contact therewith and (ii) a second, opposing end that is configured to rotationally engage a second end fitting.
 27. The apparatus of claim 26 wherein the first end fitting is a pin fitting and the second end fitting is a box fitting.
 28. The apparatus of claim 26 wherein the drive dog housing and the second end fitting are configured to cooperate to capture the second group of electrical isolators therebetween.
 29. The apparatus of claim 28 wherein said second group of electrical isolators comprises a plurality of cylindrical elongated members captured in a uniformly spaced apart distribution around a centerline of the housing.
 30. The apparatus of claim 29 wherein the second end of the drive dog housing defines a peripheral endwall that is arranged in a confronting relationship with a peripheral side margin of the second end fitting when the drive dog housing rotationally engages the second end fitting to cooperatively define a plurality of pockets that such that one of the cylindrical elongated members is captured in each pocket.
 31. The apparatus of claim 30 wherein each pocket includes a first cylindrically shaped shoulder, forming part of the drive dog housing, and a second cylindrically-shaped shoulder, forming part of the second end fitting, that confronts the first cylindrically-shaped shoulder in said confronting relationship to support an elongation axis of each cylindrical elongated member at least approximately radially with respect to said centerline.
 32. The apparatus of claim 28 wherein said second group of electrical isolators comprises a plurality of spherical members captured in a uniformly spaced apart distribution around a centerline of the housing.
 33. The apparatus of claim 32 wherein the second end of the drive dog housing defines a peripheral endwall that is arranged in a confronting relationship with a peripheral side margin of the second end fitting when the drive dog housing rotationally engages the second end fitting to cooperatively define a plurality of spherical pockets to capture one of the spherical members in each spherical pocket between the drive dog housing and the second end fitting.
 34. The apparatus of claim 26 wherein the drive dog housing defines an internal passage to rotationally receive an extension of the second end fitting and the extension defines an aperture to removably receive a clamp nut in electrical contact with the second end fitting such that the first group of electrical isolators is captured between the drive dog housing and the clamp nut, and the clamp nut cooperates with the second end fitting to form an electrical path that is electrically isolated from the first end fitting and the drive dog housing.
 35. The apparatus of claim 34 wherein the clamp nut includes a head that is supported in an interior passage that is defined by the first end fitting for coupling an electrical signal from the interior passage to the second end fitting via the clamp nut.
 36. The apparatus of claim 35 wherein the clamp nut and the extension of the second end fitting are configured for threaded engagement.
 37. The apparatus of claim 1 wherein the housing is configured to subject a selected one of the first and second groups of electrical isolators to a flexural force responsive to a rotational torque that is applied to the drill string by the drill rig.
 38. The apparatus of claim 37 wherein the housing is further configured to subject the selected one of the first and said groups to the flexural force without subjecting the other one of the first and second groups to the flexural force.
 39. The apparatus of claim 1 wherein each member of said first group of electrical isolators includes an identical peripheral outline and said housing captures the plurality of members in a uniformly spaced apart distribution around a centerline of the housing.
 40. The apparatus of claim 39 wherein each one of said first group of electrical isolators is spherical in configuration.
 41. The apparatus of claim 40 wherein each spherical member is formed having a solid core.
 42. The apparatus of claim 39 wherein said housing supports eight of said members as the first group.
 43. The apparatus of claim 39 wherein each member of the first group is formed from silicon nitride.
 44. The apparatus of claim 1 wherein each one of said second group of electrical isolators includes an identical peripheral outline and said housing captures the plurality of members of the second group in a uniformly spaced apart distribution around a centerline of the housing.
 45. The apparatus of claim 44 wherein each one of said second group of electrical isolators is spherical in configuration.
 46. The apparatus of claim 45 wherein each spherical member is formed having a solid core.
 47. The apparatus of claim 45 wherein said housing supports twelve of said members as the second group.
 48. The apparatus of claim 44 wherein each member of the second group is formed from silicon nitride.
 49. The apparatus of claim 1 wherein said housing is configured to support the first and second groups of electrical isolators under a compressive preload that is applied such that an overall compressive force that is applied to each electrical isolator varies responsive to push and pull forces that are applied to the drill string by the drill rig.
 50. The apparatus of claim 49 wherein said housing is electrically conductive.
 51. The apparatus of claim 49 wherein said housing is configured to maintain at least some compressive force on each electrical isolator corresponding to a range of said push and pull forces and based on given values of push and pull thrust that the drill rig is capable of applying to the drill string.
 52. An apparatus for use in combination with a drill string that is electrically conductive and extends from an inground distal end, that includes an inground tool, to a drill rig, said drill rig configured to rotate the drill string which applies a rotational torque to the drill string, said apparatus comprising: a housing that is configured to support a group of electrical isolators to electrically isolate a downhole portion of the drill string from an uphole portion of the drill string and configured to support the group of electrical isolators subject only to a compressive force responsive to the rotational torque.
 53. The apparatus of claim 52 wherein said housing defines a through passage that aligns with a through hole of the drill string when the housing is inserted into the drill string.
 54. The apparatus of claim 52 wherein the electrical isolators are formed from a ceramic material.
 55. The apparatus of claim 54 wherein the ceramic material is a toughened zirconia.
 56. The apparatus of claim 2 wherein said group of electrical isolators comprises a plurality of elongated members and said housing captures the plurality of elongated members in a uniformly spaced apart distribution around a centerline of the housing.
 57. The apparatus of claim 56 wherein each one of the plurality of elongated members is a cylindrical member defining an elongation axis and said housing supports each one of the plurality of cylindrical members having said elongation axis extending at least approximately radially from said centerline.
 58. The apparatus of claim 57 wherein said drill rig is configured to apply rotation to the drill string and wherein the housing is configured to apply the compressive force to the cylindrical members to transfer the rotation to the inground end of the drill string.
 59. The apparatus of claim 58 wherein the compressive force is applied to a cylindrical sidewall of each cylindrical member.
 60. The apparatus of claim 57 wherein said housing supports six of said cylindrical members.
 61. A method for electrically isolating a downhole portion of a drill string from an uphole portion of the drill string which drill string includes an inground distal end having an inground tool such that the drill string extends from the inground distal end to the drill rig, said method comprising: in a housing which housing has a housing length, supporting a first group of electrical isolators and a second group of electrical isolators such that the first group and the second group are in a spaced apart relationship along said housing length; and subjecting a first one of the first and second groups to a first compressive force responsive to the drill rig pushing on the drill string and subjecting the other one of the first and second groups to a second compressive force responsive to the drill rig pulling on the drill string without subjecting either of the first and second groups to a tension force during said pushing and pulling by the drill rig to form an electrically isolating break in the drill string.
 62. The method of claim 61 including configuring the housing for insertion into the drill string to thereafter form part of an overall length of the drill string.
 63. The method of claim 61 including configuring the housing as part of the inground tool.
 64. The method of claim 61 including using an identical material for the first isolators and the second isolators.
 65. The method of claim 61 including using a ceramic material for the first isolators and the second isolators.
 66. The method of claim 65 including using at least one of a toughened zirconia and silicon nitride as the ceramic material.
 67. The method of claim 61 including providing each electrical isolator in a spherical shape.
 68. The method of claim 61 including forming the first group of electrical isolators as a plurality of elongated members and capturing the plurality of elongated members in said housing in a uniformly spaced apart distribution around a centerline of the housing.
 69. The method of claim 68 including forming each one of the plurality of elongated members as a cylindrical member defining an elongation axis and supporting each one of the plurality of cylindrical members having said elongation axis at least approximately parallel to said centerline.
 70. The method of claim 69 including pulling on the drill string from the drill rig to subject the plurality of cylindrical members to said second compressive force.
 71. The method of claim 70 including applying the compressive force to a pair of opposing end surfaces of each cylindrical member.
 72. The method of claim 71 including supporting six of said cylindrical members in said housing.
 73. The method of claim 61 including forming the second group of electrical isolators as a plurality of elongated members and capturing the plurality of elongated electrical isolators in said housing in a uniformly spaced apart distribution around a centerline of the housing.
 74. The method of claim 73 including forming each one of the plurality of elongated members as a cylindrical member defining an elongation axis and supporting each one of the plurality of cylindrical members having said elongation axis extending at least approximately radially from said centerline.
 75. The method of claim 74 including forming each cylindrical member having a solid core.
 76. The method of claim 74 including pushing on the drill string from the drill rig to subject the elongated members to said first compressive force.
 77. The method of claim 76 including applying said first compressive force to opposing side margins of a cylindrical sidewall of each cylindrical member.
 78. The method of claim 74 wherein said drill rig is configured to apply rotation to the drill string and including applying an additional compressive force to each cylindrical member for transferring the rotation to the downhole portion of the drill string.
 79. The method of claim 78 including applying the additional compressive force to a cylindrical sidewall of each cylindrical member.
 80. The method of claim 76 including supporting six of said cylindrical members in said housing.
 81. The method of claim 61 including subjecting a selected one of the first and second groups of electrical isolators to a flexural force responsive to a rotational torque that is applied to the drill string by the drill rig.
 82. The method of claim 81 including subjecting the selected one of the first and said groups to the flexural force without subjecting the other one of the first and second groups to the flexural force.
 83. The method of claim 61 wherein each member of said first group of electrical isolators includes an identical peripheral outline and said method includes capturing the plurality of members in a uniformly spaced apart distribution around a centerline of the housing.
 84. The method of claim 83 wherein each electrical isolator is formed as being spherical in configuration.
 85. The method of claim 84 wherein each electrical isolator is formed having a solid core.
 86. The method of claim 61 including supporting the first and second groups of electrical isolators under a compressive preload that is applied by the housing such that an overall compressive force that is applied to each electrical isolator varies responsive to push and pull forces that are applied to the drill string by the drill rig.
 87. The method of claim 86 including maintaining at least some compressive force on each electrical isolator responsive to any value of the push and pull force applied to the drill string by the drill rig based on given values of push and pull thrust that the drill rig is capable of applying to the drill string.
 88. In forming an electrically isolating break in an electrically conductive drill string that extends from a drill rig to an inground distal end, with said drill rig configured to rotate the drill string to apply a rotational torque to the inground distal end, a method comprising: arranging a housing in the drill string to support an arrangement of elongated members that are electrical insulators to electrically isolate a downhole portion of the drill string, including said distal end, from an uphole portion of the drill string and subjecting the elongated members only to a compressive force responsive to the rotational torque.
 89. The method of claim 88 including defining a through passage in the housing that aligns with a through hole in the drill string when the housing is inserted into the drill string.
 90. The method of claim 88 including providing the electrically insulating material as a ceramic material.
 91. The method of claim 90 wherein the ceramic material is a toughened zirconia.
 92. The method of claim 88 including capturing the plurality of elongated members in the housing in a uniformly spaced apart distribution around a centerline of the housing.
 93. The method of claim 92 including configuring each one of the plurality of elongated members as a cylindrical member defining an elongation axis and supporting each one of the plurality of cylindrical members in the housing having said elongation axis extending at least approximately radially from said centerline.
 94. The method of claim 93 wherein said drill rig is configured to apply rotation to the drill string and wherein said method includes applying the compressive force to the cylindrical members from the housing to transfer the rotation to the downhole portion of the drill string.
 95. The method of claim 94 including applying the compressive force to a cylindrical sidewall of each cylindrical member.
 96. The method of claim 93 including configuring the housing to support six of said cylindrical members.
 97. An apparatus for use in combination with an electrically conductive drill string and which drill string extends from an inground distal end, including an inground tool, to a drill rig, said apparatus comprising: a plurality of electrical isolators; and a housing defining a through passage and having an elongated housing length that is configured to support the plurality of electrical isolators under a compressive preload that is applied by the housing in a direction that is aligned with the elongated housing length such that an overall compressive force that is applied to the electrical isolators varies responsive to push and pull forces that are applied to the drill string by the drill rig and the electrical isolators cooperate with the housing to form an electrically isolating gap between said inground distal end and said drill rig.
 98. The apparatus of claim 97 wherein said housing is configured to maintain at least some compressive force on each electrical isolator corresponding to a range of said push and pull forces and based on given values of push and pull thrust that the drill rig is capable of applying to the drill string.
 99. The apparatus of claim 98 wherein said housing is configured to support the plurality of electrical isolators as a first group and a second group in a spaced apart relationship along said housing length and surrounding the through passage such that, responsive to the drill rig pushing on the drill string, a first one of the first and second groups is subject to an increase in compressive force while subjecting the second group to a decrease in compressive force.
 100. The apparatus of claim 99 wherein said housing, responsive to the drill rig pulling on the drill string, is configured to subject a second one of the first and second groups to an increase in compressive force while subjecting the other one of the first and second groups to a decrease in compressive force.
 101. A method for forming an electrically isolated gap in an electrically conductive drill string between an inground distal end of the drill string including an inground tool and a drill rig to which the drill string extends, said method comprising: providing a plurality of electrical isolators; forming a housing defining a through passage and having an elongated housing length that is configured to support the plurality of electrical isolators; and applying a compressive preload to the electrical isolators from the housing in a direction that is aligned with an elongation axis of the drill string such that an overall compressive force that is applied to the electrical isolators varies responsive to push and pull forces that are applied to the drill string by the drill rig and the electrical isolators cooperate with the housing to form an electrically isolated gap between said inground distal end and said drill rig.
 102. The method of claim 101 including maintaining at least some compressive force on each electrical isolator responsive to any value of the push and pull force applied to the drill string by the drill rig based on given values of push and pull thrust that the drill rig is capable of applying to the drill string.
 103. The method of claim 102 including configuring said housing to support the plurality of electrical isolators as a first group and a second group in a spaced apart relationship along said housing length and surrounding the through passage such that, responsive to the drill rig pushing on the drill string, a first one of the first and second groups is subject to an increase in compressive force while subjecting the second group to a decrease in compressive force.
 104. The method of claim 103 including further configuring said housing subject a second one of the first and second groups to an increase in compressive force responsive to the drill rig pulling on the drill string while subjecting the other one of the first and second groups to a decrease in compressive force.
 105. An apparatus for use in combination with a drill string that is electrically conductive and extends from an inground distal end that includes an inground tool, to a drill rig, said apparatus comprising: a first group of electrical isolators and a second group of electrical isolators; a first housing body that is electrically conductive and defines a first drill string fitting; a second housing body that is electrically conductive having opposing first and second ends and configured to cooperate with the first housing body to support the first group of electrical isolators at the first end of the second housing body and the second group of electrical isolators at the second end of the second housing body such that the first housing body is electrically isolated from the second housing body; and an interchangeable body that is electrically conductive and configured for removably fixed engagement with the second end of the second housing body and said interchangeable body is selectable as each of (i) said inground tool to form the inground distal end of the drill string and (ii) a second, opposing drill string fitting such that the apparatus is insertable into a joint in the drill string that would otherwise be formed between adjacent drill rods as the drill string is extended.
 106. The apparatus of claim 105 wherein the interchangeable body, as an inground tool, is selectable as each of a drill head and a reamer.
 107. The apparatus of claim 105 wherein the first group of isolators is captured between an end face of the first end of the second housing body and the first housing body.
 108. The apparatus of claim 105 wherein the first housing body cooperates with the second housing body to apply a compressive preload to the first and second groups of isolators such that a corresponding preload compression force is applied to the second housing body from the first and second opposing ends thereof and a portion of the first housing body is subject to a tension force that is complementary to the corresponding preload compression force.
 109. A method to provide an apparatus for use in combination with a drill string that is electrically conductive and extends from an inground distal end that includes an inground tool, to a drill rig, said method comprising: providing a first group of electrical isolators and a second group of electrical isolators; configuring a first housing body as electrically conductive and to define a first drill string fitting; configuring a second housing body as electrically conductive and to have opposing first and second ends and to cooperate with the first housing body to support the first group of electrical isolators at the first end of the second housing body and the second group of electrical isolators at the second end of the second housing body such that the first housing body is electrically isolated from the second housing body; and forming an interchangeable body that is electrically conductive and configured for removably fixed engagement with the second end of the second housing body and said interchangeable body is selectable as each of (i) said inground tool to form the inground distal end of the drill string and (ii) a second, opposing drill string fitting such that the apparatus is insertable into a joint in the drill string that would otherwise be formed between adjacent drill rods as the drill string is extended.
 110. The method of claim 109 including selecting the interchangeable body as one of an inground tool, a drill head and a reamer.
 111. The method of claim 109 including capturing the first group of isolators between an end face of the first end of the second housing body and the first housing body.
 112. The method of claim 109 including further configuring the first housing body to cooperate with the second housing body to apply a compressive preload to the first and second groups of isolators such that a corresponding preload compression force is applied to the second housing body from the first and second opposing ends thereof and a portion of the first housing body is subject to a tension force that is complementary to the corresponding preload compression force.
 113. An apparatus for use in combination with a drill string that is electrically conductive and extends from an inground distal end that includes an inground tool, to a drill rig, said apparatus comprising: a first group of electrical isolators and a second group of electrical isolators; a first housing body that is electrically conductive and defines a first drill string fitting; a second housing body that is electrically conductive having opposing first and second ends and configured to cooperate with the first housing body to support the first group of electrical isolators at the first end of the second housing body and the second group of electrical isolators at the second end of the second housing body such that the first housing body is electrically isolated from the second housing body; and an interchangeable body that is electrically conductive and configured for removably fixed engagement with the second end of the second housing body and said interchangeable body is configured to perform a selected one of at least two different inground operations. 